Voltage dependence of theChara proton pump revealed by current-voltage measurement during rapid metabolic blockade with cyanide

Summary It is generally agreed that solute transport across theChara plasma membrane is energized by a proton electrochemical gradient maintained by an H⁺-extruding ATPase. Nonetheless, as deduced from steady-state current-voltage (I-V) measurements, the kinetic and thermodynamic constraints on H⁺-ATPase function remain in dispute. Uncertainties necessarily surround long-term effects of the relatively nonspecific antagonists used in the past; but a second, and potentially more serious problem has sprung from the custom of subtracting, across the voltage spectrum, currents recorded following pump inhibition from currents measured in the control. This practice must fail to yield the trueI-V profile for the pump when treatments alter the thermodynamic pressure on transport.We have reviewed these issues, using rapid metabolic blockade with cyanide and fitting the resultant whole-cellI-V and difference-current-voltage (dI-V) relations to a reaction kinetic model for the pump and parallel, ensemble leak. Measurements were carried out after blocking excitation with LaCl₃, so that steady-state currents could be recorded under voltage clamp between –400 and +100 mV. Exposures to 1mm NaCN (CN) and 0.4mm salicylhydroxamic acid (SHAM) depolarized (positive-going)Chara membrane potentials by 44–112 mV with a mean half time of 5.4±0.8 sec (n=13). ATP contents, which were followed in parallel experiments, decayed coincidently with a mean half time of 5.3±0.9 sec ([ATP] _t=0, 0.74±0.3mm; [ATP] _t=x , 0.23±0.02mm). Current-voltage response to metabolic blockade was described quantitatively in context of these changes in ATP content and the consequent reduction in pump turnover rate accompanied by variable declines in ensemble leak conductance. Analyses ofdI-V curves (±CN+SHAM) as well as of families ofI-V curves taken at times during CN+SHAM exposures indicated a stoichiometry for the pump of one charge (H⁺) transported per ATP hydrolyzed and an equilibrium potential near –420 mV at neutral external pH; under these conditions, the pump accounted for approximately 60–75% of the total membrane conductance nearV _m. Complementary results were obtained also in fitting previously publishedI-V data gathered over the external pH range 4.5–7.5 Kinetic features deduced for the pump were dominated by a slow step preceding H⁺ unloading outside, and by recycling and loading steps on the inside which were in rapid equilibrium. These characteristics predict, in marked contrast to the situation forNeurospora, that cytoplasmic acid loads inChara should shift the pumpI-V curve negative-going along the voltage axis with little change in maximum current output at positive voltages.     

Plasmodium falciparum: physiological interactions with the human sickle cell.

The malaria parasite, Plasmodium falciparum, enhances the rate and extent of sickling of infected hemoglobin S heterozygous human erythrocytes. Upon sickling of the host cell, the parasite is killed. Parasite-free lysates of highly infected cells were analyzed to determine the mechanism by which sickling is enhanced. The intraerythrocytic pH of the infected cell was estimated to be 0.4 units below that of the uninfected cell, a difference which could result in a 20-fold increase in the extent of sickling under physiological conditions. Sickle-cell hemoglobin (HbS) heterozygous (AS) erythrocytes had decreased intracellular potassium after 24 hr of culture under conditions which cause sickling and parasite death. When infected AS cells were cultured in high-potassium medium under these conditions the parasites were protected. The medium did not prevent sickling but did maintain normal intracellular potassium levels. It is suggested that sequestration of trophozoite-infected AS cells in the venules leads to the sickling of the host cell, loss of erythrocytic potassium, and parasite death. The resulting attenuation of parasite multiplication would favor the survival of the HbS heterozygote and maintain the HbS gene at high frequencies in areas endemic for falciparum malaria.     

The major growth current through lily pollen tubes enters as K+ and leaves as H+

Growing lily (Lilium longiflorum Thunb.) pollen always drive a current into their tubes and out of their grains. The only external ions needed for growth (and the growth current) are K⁺, H⁺, and Ca²⁺. Increases in K⁺ immediately stimulate the current; while decreases in K⁺ immediately inhibit it. Comparable changes in H⁺ have the opposite effect; while those in Ca²⁺ have very little effect. We infer that most of the steady growth current is carried in by a potassium leak and out by a proton pump; but other considerations indicate that a minor, but controlling, component of the inward current consists of calcium ions.     

Mitochondrial abundance and function in muscle from beef steers with divergent residual feed intakes

The objective of this study was to evaluate the relationship between muscle mitochondrial function and residual feed intake (RFI) in growing beef cattle. A 56-day feeding trial was conducted with 81 Angus × Hereford steers (initial BW = 378 ± 43 kg) from the University of California Sierra Foothills Research Station (Browns Valley, CA, USA). All steers were individually fed the same finishing ration (metabolizable energy = 3.28 Mcal/kg DM). Average daily gain (ADG), DM intake (DMI) and RFI were 1.82 ± 0.27, 8.89 ± 1.06 and 0.00 ± 0.55 kg/day, respectively. After the feeding trial, the steers were categorized into high, medium and low RFI groups. Low RFI steers consumed 13.6% less DM (P < 0.05) and had a 14.1% higher G : F ratio (P < 0.05) than the high RFI group. No differences between RFI groups were found in age, ADG or BW (P > 0.10). The most extreme individuals from the low and high RFI groups were selected to assess mitochondrial function (n = 5 low RFI and n = 6 high RFI). Mitochondrial respiration was measured using an oxygraph (Hansatech Instruments Ltd., Norfolk, UK). State 3 and State 4 respiration rates were similar between both groups (P > 0.10). Respiratory control ratios (RCRs, i.e., State 3 : State 4 oxygen uptakes) declined with animal age and were greater in low RFI steers (4.90) as compared to high RFI steers (4.26) when adjusted for age by analysis of covariance (P = 0.003). Mitochondrial complex II activity levels per gram of muscle were 42% greater in low RFI steers than in high RFI steers (P = 0.004). These data suggest that skeletal muscle mitochondria have greater reserve respiratory capacity and show greater coupling between respiration and phosphorylation in low RFI than in high RFI steers.     

食管癌患者术前营养风险评估及与术后吻合口瘘和住院时间的关系研究

摘要 目的：评估食管癌患者术前营养风险及其影响因素,并分析其与术后吻合口瘘和住院时间的关系。方法：回顾性分析2017年1月至2020年12月在合肥市第二人民医院胸外科行手术治疗的105例食管癌患者的临床资料,患者术前均完善营养风险筛查表-2002（NRS-2002）对其营养风险的评估,根据评估结果分为营养风险组（≥3分,43例）和无营养风险组（＜3分,62例）,采用单因素及多因素Logistic回归分析食管癌患者术前营养风险的影响因素,比较不同术前营养风险状态患者术后吻合口瘘发生率以及住院时间的差异。结果：食管癌患者的术前营养风险较高,营养风险发生率为40.95%（43/105）。单因素分析结果显示,营养风险组年龄≥65岁、入院体质量指数＜18.5 kg/m²、术前接受过新辅助放化疗、过去1周膳食摄入不足、术前白蛋白＜35 g/L的患者比例高于无营养风险组（P＜0.05）。多因素Logistic回归分析结果显示,术前接受过新辅助放化疗、过去1周膳食摄入不足、术前白蛋白＜35 g/L是食管癌患者术前存在营养风险的危险因素（P＜0.05）。营养风险组术后胸腔吻合口瘘、颈部吻合口瘘发生率高于无营养风险组（P＜0.05）,住院时间长于无营养风险组（P＜0.05）。结论：术前新辅助放化疗、过去1周膳食摄入情况、术前白蛋白水平是食管癌患者术前营养风险的影响因素,术前营养风险会增加患者术后吻合口瘘发生风险,延长患者住院时间。     

Proton leak modulation in testicular mitochondria affects reactive oxygen species production and lipid peroxidation

Mitochondrial proton leak can account for almost 20% of oxygen consumption and it is generally accepted that this process contributes to basal metabolism. In order to clarify the role of basal proton leak in testicular mitochondria, we performed a comparative study with kidney and liver mitochondrial fractions. Proton leak stimulated by linoleic acid and inhibited by guanosine diphosphate (GDP) was detected, in a manner that was correlated with protein levels for uncoupling protein 2 (UCP2) in the three fractions. Modulation of proton leak had an effect on reactive oxygen species production as well as on lipid peroxidation, and this effect was also tissue‐dependent. However, a possible role for the adenine nucleotide transporter (ANT) in testicular mitochondria proton leak could not be excluded. The modulation of proton leak appears as a possible and attractive target to control oxidative stress with implications for male gametogenesis. Copyright © 2010 John Wiley & Sons, Ltd.     

Oxidative phosphorylation by in situ synaptosomal mitochondria from whole brain of young and old rats

Synaptosomes, isolated from the whole brain of young (3 months) and old (24 months) rats were used to study the major bioenergetic systems of neuronal mitochondria in situ, within the synaptosome. Approximately 85% of the resting oxygen consumption of synaptosomes from both young and old rats was a result of proton leak (and possibly other ion cycling) across the mitochondrial inner membrane. There were no significant differences between synaptosomes from the young and old rats in the kinetic responses of the substrate oxidation system, the mitochondrial proton leak and the phosphorylation system to changes in the proton electrochemical gradient. Flux control coefficients of 0.71, 0.27 and 0.02 were calculated for substrate oxidation system, phosphorylation system and the proton leak, respectively, at maximal ATP producing capacity in synaptosomes from young animals. The corresponding values calculated for synaptosomes from old animals were 0.53, 0.43 and 0.05. Thus substrate oxidation had greatest control over oxygen consumption at maximal phosphorylating capacity for synaptosomes from whole brain, with proton leak, having little control under maximal ATP producing capacity. The uncoupled rate of oxygen consumption, in the presence of the mitochondrial uncoupler, carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP), was significantly lower (p = 0.0124) in synaptosomes from old rats (6.08 +/- 0.42, n = 11) when compared with those from the young rats (7.87 +/- 0.48, n = 8). Thus, there is an impaired flux through the substrate oxidation system is synaptosomes from old rats, as compared to synaptosomes from the young animals. These in situ results may have important implications for the interpretation of theories that age-dependent impairment of mitochondrial energy production may result in increased susceptibility to neurodegeneration.     

Brite/beige fat and UCP1 — is it thermogenesis?

The presence of two distinct types of adipose tissue, which have opposing functions, has been known for decades. White adipose tissue (WAT) is the main tissue of energy storage, while brown adipose tissue (BAT) dissipates energy as heat and is required for non-shivering thermoregulation. In the last few years, a third type of adipocyte was identified, termed the brite (“brown and white”) or beige adipocyte. Their physiological control and role, however, are not fully clarified. Brite/beige adipocytes have a positive impact on systemic metabolism that is generally explained by the thermogenesis of brite/beige adipocytes; although thermogenesis has not been directly measured but is mostly inferred by gene expression data of typical thermogenic genes such as uncoupling protein 1 (UCP1). Here we critically review functional evidence for the thermogenic potential of brite/beige adipocytes, leading to the conclusion that direct measurements of brite/beige adipocyte bioenergetics, beyond gene regulation, are pivotal to quantify their thermogenic potential. In particular, we exemplified that the massive induction of UCP1 mRNA during the browning of isolated subcutaneous adipocytes in vitro is not reflected in significant alterations of cellular bioenergetics. Herein, we demonstrate that increases in mitochondrial respiration in response to beta-adrenergic stimulus can be independent of UCP1. Using HEK293 cells expressing UCP1, we show how to directly assess UCP1 function by adequate activation in intact cells. Finally, we provide a guide on the interpretation of UCP1 activity and the pitfalls by solely using respiration measurements. The functional analysis of beige adipocyte bioenergetics will assist to delineate the impact of browning on thermogenesis, possibly elucidating additional physiological roles and its contribution to systemic metabolism, highlighting possible avenues for future research. This article is part of a Special Issue entitled: 18th European Bioenergetic Conference.     

Mitochondrial metabolism during fasting-induced daily torpor in mice

During fasting, mice (Mus musculus) undergo daily bouts of torpor, considerably reducing body temperature (T_b) and metabolic rate (MR). We examined females of different laboratory strains (Balb/c, C57/6N, and CD1) to determine whether liver mitochondrial metabolism is actively reduced during torpor. In all strains, we found that state 3 (phosphorylating) respiration rate measured at 37 °C was reduced up to 35% during torpor for at least one of the substrates (glutamate and succinate) used to fuel respiration. The extent of this suppression varied and was correlated with T_b at sampling. This suggests that, at the biochemical level, the transition to and from a hypometabolic torpid state is gradual. In fasted non-torpid animals, T_b and MR still fluctuated greatly: T_b dropped by as much as 4 °C and MR was reduced up to 25% compared to fed controls. Changes in T_b and MR in fasted, non-torpid animals were correlated with changes in mitochondrial state 3 respiration rate measured at 37 °C. This suggests that fasting mice may conserve energy even when not torpid by occasionally reducing T_b and mitochondrial oxidative capacity to reduce MR. Furthermore, proton conductance was higher in torpid compared to non-torpid animals when measured at 15 °C (the lower limit of torpid T_b). This pattern is similar to that reported previously for daily torpor in Phodopus sungorus.